KR20070032334A - Method and system for determining a power level for communication in a wireless network - Google Patents

Abstract

The present invention relates to a method for determining a power level for communication in a wireless network. A power level determination method for communicating in a wireless network capable of communicating with a plurality of mobile stations in a service area, the method comprising: generating a probe message including a power level indicator, wherein the power level indicator determines a transmit power level of the probe message; Indicates that the probe message requires the base station to access the system of the mobile station. The probe message is sent to the base station at the predetermined power level.

Probe message, transmit power control, connection probe

Description

METHOD AND SYSTEM FOR DETERMINING A POWER LEVEL FOR COMMUNICATION IN A WIRELESS NETWORK}

The present invention relates to a method and system for communication in a wireless network, and more particularly to a method and system for determining power level for communication in a wireless network.

Increasingly, cellular phones and wireless networks are on the rise. Mobile stations, such as cellular phones, perform a system connection procedure that connects to a wireless network to receive services such as call origination, call answering, registration, data burst request or response, order request or response. Basically, a mobile station enters a system connection state when it is necessary to transmit a message to a base station of a wireless network without using a traffic channel.

The mobile station's attempt to transmit a message wirelessly is called a connection probe. Each message sent by the mobile station on the access channel is inserted into one access probe. A series of connection probes that transmit while increasing the power level is called a connection probe sequence. The entire process by which a mobile station sends a message over an access channel and receives or fails to receive a response signal from a base station is defined as a connection attempt, which is made up of several access probe sequences.

The connection attempt is terminated when the second layer accepts an acknowledgment of the transmitted message within a predetermined time or transmits the maximum number of access probe sequences, but does not receive the acknowledgment. When the accept response is received at the base station, generally the service requested by the mobile station is provided.

However, in the conventional wireless network, when the mobile station subsequently wants another service, the base station or the mobile station cannot use the information obtained from the previous connection attempt and must start the whole process from the beginning. It is also not possible to use the information related to the connection attempt which will help the base station to provide better service to the mobile stations in its service area.

Therefore, there is a need for an improved wireless network that facilitates access attempts more efficiently and provides useful information to base stations in accordance with access attempts. In particular, a successful connection that can not only inform the base station of power levels, but also can be used to determine coverage holes at the base station, resolve link imbalances, perform good power control and set up calls faster. There is a need for a wireless network that can provide a mobile station that can make multiple connection attempts through probes.

Accordingly, it is an object of the present invention to provide a method and system for determining a power level for communicating in a wireless network.

Another object of the present invention is to provide a method and system for reducing unnecessary processes when establishing a call in a wireless communication network.

It is yet another object of the present invention to provide a method and system for determining service defects and resolving link imbalances in a wireless communication network.

According to a preferred embodiment of the present invention for achieving the above object, in a method for determining a power level for communicating in a wireless network capable of communicating with a plurality of mobile stations in a service area, generating a probe message including a power level indicator And the power level indicator indicates the transmit power level of the probe message, and the probe message requests the base station to access the system of the mobile station. The probe message is sent to the base station at the predetermined power level.

According to an embodiment of the present invention, a connection parameter message including an initial power level and a power level increment is received from a base station.

According to another embodiment of the present invention, the power level indicator includes a probe number of the probe message, and the connection parameter message further includes a maximum probe number.

According to another embodiment of the present invention, a response to the probe message is received from the base station and communicates with the base station at the predetermined power level.

According to another embodiment of the present invention, the probe message includes an automatic retransmission request message.

According to another embodiment of the present invention, the probe message is transmitted to a plurality of base stations.

According to another embodiment of the present invention, the power level indicator includes a probe number of the probe message.

According to another embodiment of the present invention, the probe message further includes a service area indicator.

According to another embodiment of the present invention, the service area indicator includes a connection sequence number indicating a connection sequence associated with the probe message.

1 is an illustration of a wireless network capable of determining a power level for communication in accordance with the present invention;

2 is an illustration of a base station capable of detecting a power level for communicating with a mobile station in accordance with the present invention;

3 is a flowchart of determining a power level for performing communication in a base station according to the present invention;

4 is an illustration of a mobile station capable of controlling a power level to communicate with a base station in accordance with the present invention;

5 is a flowchart in determining a power level for performing communication in a mobile station according to the present invention.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. In describing the present invention, when it is determined that the detailed description of the related known function or configuration may unnecessarily obscure the gist of the present invention, the detailed description thereof will be omitted.

Before describing the composition of the invention, terms and phrases used throughout this specification are defined. "Include" and "comprise", and their derivatives, are meant to encompass no limitations. The term "or" is used in its inclusive sense "and / or". "Each" means all components within at least one set of defined items. The term "associated with, associated therewith" and its derivatives include to include, be included within, interconnect with, contain, be contained within, and connect (connect to or with, couple to or with), be communicable with, cooperate with, interleave, juxtapose, be proximate to, be bound to or with ), Have (have), have a property of, etc. "Controller" means a device, system or part of such a system that controls at least one operation, which device may be implemented through hardware, firmware, software, or a combination of at least two of the above listed. It should be noted that the functions associated with any particular controller may be centralized or distributed, whether locally or remotely. Those of ordinary skill in the art should understand that the definitions that appear throughout this specification may, in most cases, if not most of the cases, apply to future uses as well as future uses of the terms and phrases. .

1 is a block diagram of a wireless network capable of determining a power level for communication in accordance with the present invention. The wireless network 100 is composed of a plurality of cells (121 to 123), each cell is a communication area of the base stations (101, 102 or 103). The base stations 101-103 communicate with a plurality of mobile stations 111-114 over a CDMA channel, for example in accordance with the IS-2000 standard (i.e., the CDMA2000 standard). According to one preferred embodiment of the present invention, the mobile stations 111 to 114 may be wireless devices capable of communicating with the base stations 101 to 103 via a wireless link. Such wireless devices include conventional cellular phones, PCS terminals, PDA terminals, portable computers, telemetry devices, and the like.

The present invention is not limited to mobile devices but also applies to other kinds of radio access terminals, including fixed radio terminals and the like. For convenience of explanation, the following description will be made only to the mobile station. However, the term "mobile station" as used in the claims and in the following text includes not only mobile devices such as cellular phones, wireless notebook computers, but also fixed wireless terminals such as machine monitors with wireless functionality.

Approximate boundaries of the cells 121 to 123 where the base stations 101 to 103 are located are indicated by dotted lines. Although the cells are generally shown in the form of a circle, these are just shown for convenience of description and may take other irregular shapes according to the structure of the selected cell, natural obstacles, and artificial obstacles.

As is well known, each cell is divided into a plurality of sectors, each sector having a directional antenna connected to a base station. In the embodiment shown in FIG. 1, the base station is located in the center of the cell, but in another embodiment, the directional antenna may be located at the corner of the cell. The system according to the invention is not limited to a particular cell structure.

In one embodiment of the invention, each base station has a base station controller (BSC) and one or more base station transmit / receive subsystems (BTS). A base station controller is a device that manages wireless communication resources for specific cells in a wireless communication network, including base station transmit and receive subsystems. The base station transmit / receive subsystem includes a radio frequency (RF) transceiver, an antenna, and other electrical devices in each cell. These electrical devices include air conditioning units, heater units, power supplies, telephone line interfaces, RF transmitters and RF receivers. In order to more simply and clearly describe the operation of the present invention, the base station transmit / receive subsystem and associated base station controller of each cell are referred to as base stations (BSs) 101 to 103.

The base stations 101 to 103 transmit mutual voice signals and data signals and transmit voice signals and data signals to a public telephone network (PSTN) and a mobile switching center (MSC) 140, which are not shown, through the communication line 131. The base stations 101 to 103 also transmit data signals, such as packet data, to the Internet and the packet data server node (PDSN) 150, which are not shown, through the communication line 131. The packet control function unit (PCF) 190 controls the packet data flow between the base stations 101-103 and the PDSN 150. PCF 190 may be configured as a PDSN 150 or part of MSC 140, or as a separate device in communication with PDSN 150 as shown in FIG. 1. The communication line 131 provides a control signal connection path between the MSC 140 and the base stations 101 to 103 which mutually establish a connection for a voice and a data line.

The communication line 131 may be a connection means such as T1, T3, fiber optic link, network packet data backbone connection, or other type of data connection. The communication line 131 connects each vocoder in the BSC and the switches in the MSC 140. Through the connection of the communication line 131, an analog voice signal or a digital voice signal may be transmitted in a pulse code modulation (PCM) format, an Internet protocol (IP) format, an asynchronous transmission mode (ATM) format, or the like.

The MSC 140 is a switching device that provides and coordinates services between wireless networks and subscribers of external networks such as PSTNs or the Internet. MSC 140 is well known to those skilled in the art. In embodiments of the present invention, the communication line 131 may be composed of a plurality of data links, and each data link connects each of the base stations with the MSC 140.

In the illustrated wireless network 100, the mobile station 111 is located in the cell 121 and communicates with the base station 101. Mobile station 113 is in cell 122 and communicates with base station 102. Mobile station 114 is in cell 123 and communicates with base station 103. The mobile station 112 is located close to the edge of the cell 123 and is moving to the cell 123 as indicated by the directional arrow indicated nearby. At some point the mobile station 112 enters the cell 123 and leaves the cell 121, and a handoff will occur.

According to an exemplary embodiment of the present invention, one or more of the mobile stations 111 to 114 may transmit the access probe and the access sequence number information to the base stations 101 to 103. When the mobile station, for example, the mobile station 111 performs a system connection procedure to connect to the wireless network 111 to receive services such as call origination, call answering, registration, data burst request or response, order request or response, The mobile station 111 sends a probe message to the base station 101 through an access probe. The mobile station 111 may send a probe message to one or more other base stations, for example, the base stations 102 and 103.

If the probe message is not accepted within a predetermined time, the mobile station 111 increases the power level associated with the access probe and sends another probe message. When the power level reaches a maximum, the mobile station 111 sends a probe message at the initial power level to start a new connection sequence. The mobile station 111 continues to operate until the maximum number of access procedures performed or until an acceptance response is received from the base station 101.

When the probe message is generated for each access probe, the mobile station 111 includes a power level indicator in the probe message. In addition, the mobile station 111 may also include a service area indicator. For example, the mobile station 111 may include a probe number that identifies the current probe in the current connection sequence and a connection sequence number that identifies the current connection sequence in the probe message. In one embodiment, the probe message may include an automatic retransmission request (ARQ) message.

According to the initial power level used when the mobile station 111 transmits the access probe and the increased power increase for transmission of each subsequent probe, the base station 101 accesses the connection successfully transmitted by the mobile station 111 through the probe number. Find out the power level of the probe. In addition, the base station 101 may use the access sequence number to identify the location of service defects, resolve link imbalance, and set up a call more quickly.

2 is a block diagram illustrating an internal configuration of a base station according to the present invention. As described in the description of FIG. 1, the base station 101 includes a BSC 210 and at least one BTS 220. The BSC 210 manages resources of the cell 121 including the BTS 220. According to one embodiment, the BTS 220 includes a BTS controller 225, a channel controller 235 with at least one channel element 240, a transceiver interface 245, an RF transceiver 250, an antenna array 255. ), And a power level detector 260.

The BTS controller 115 may have a processing circuit and a memory capable of executing an operation program that controls the overall operation of the BTS 220 and is in communication with the BSC 210. In the normal state, the BTS controller 225 instructs the operation of the channel controller 235. The channel controller 235 is composed of a plurality of channel elements, such as the channel element 240, each channel element operates to enable bidirectional communication through the forward channel and the reverse channel. The term "forward channel" refers to a signal transmitted from the base station 101 to the mobile stations 111 and 112, and the term "reverse channel" refers to a signal transmitted from the mobile stations 111 and 112 to the base station 101. Say. The transceiver interface 245 transmits a bidirectional channel signal between the channel controller 240 and the RF transceiver 250.

The antenna array 255 transmits the forward channel signal received from the RF transceiver to the mobile station in the service area of the base station 101. In addition, the antenna array 255 transmits the reverse channel signal received from the mobile station in the service area of the base station 101 to the RF transceiver 250. According to one embodiment of the invention, the antenna array 255 has a multi-sector antenna, such as a three-sector antenna. Here, each antenna sector is responsible for transmitting and receiving a service area corresponding to a call of about 120E. In addition, the RF transceiver 250 may include an antenna selector for selecting an antenna from among different antennas of the antenna array 255 during a transmission and reception operation.

In the illustrated embodiment, the power level detector 260 extracts a power level indicator and a service area indicator from a probe message received from a mobile station such as mobile station 111. For example, the power level detector 260 extracts a probe number and a connection sequence number from the probe message. In one embodiment, the probe message may have an ARQ message.

The power level detector 260 detects an initial power level used by the mobile station 111 when transmitting the connection probe and an increase in power during each subsequent connection probe transmission. The initial power level and each power increase are provided by the base station 101 to the mobile station 111 through an access parameter message (APM). The connection parameter message may include a maximum probe number and / or a maximum connection sequence number. However, in another embodiment, the maximum probe number and / or the maximum access sequence number may be predetermined. For example, the two numbers may be set to 16.

According to the initial power level, the power increase used in each subsequent probe, and the probe number extracted from the probe message, the power level detector 260 may know the power level of the access probe successfully transmitted by the mobile station 111. In addition, the power level detector 260 may use the extracted connection sequence number to find a service defect point, solve link imbalance, and set up a call more quickly.

3 is a control flowchart illustrating a method of determining a power level for communication in a base station according to the present invention. In order to explain the operation of the present invention more simply and clearly, it is assumed below that the base station 101 of the wireless network 100 provides a service to the mobile station 111. However, the following description applies equally to other base stations and mobile stations in the wireless network 100.

In step 305, the base station 101 initially transmits an access parameter message (hereinafter referred to as "APM") to the mobile station 111 through the call channel. The APM includes information used by the mobile station 111 when connecting to the base station 101 to request a service. For example, the APM may include the initial power level used for the initial probe as well as the power increment that the mobile station 111 uses for each subsequent probe in a particular connection sequence. The APM may also include a maximum probe number and / or a maximum access sequence number.

In step 310, the base station 101 receives a probe including a probe message from the mobile station 111. In another embodiment, the probe message may include an ARQ message. In step 315, the power level detector 260 of the base station 101 detects the power level of the probe transmitted from the mobile station 111 based on the information in the probe message. For example, the power level detector 260 may extract a probe number and a connection sequence number from the probe. The power level detector 260 may calculate the transmit power level of the reception probe by using the initial power level and the power increase previously transmitted by the base station 101 to the mobile station 111 through the APM. The base station 101 may determine the information on the service area based on the access sequence number.

In step 320, the base station 101 starts communication with the mobile station 111 at the detected power level. The base station 101 may send the updated APM to the mobile station 111 according to the detected power level in step 325. For example, the base station 101 may set the initial power level to be used by the mobile station 111 in future probes to the detected power level to increase the probe success rate earlier in the connection sequence. In addition, the base station 101 may adjust the maximum probe number and / or the maximum access sequence number. For example, the base station 101 can reduce the maximum probe number so that the final power level before the new connection sequence starts has the same value.

4 is a block diagram of a mobile station according to one embodiment of the present invention. Mobile station 111 is shown by way of example only. Thus, the configuration shown and described for the mobile station 111 also applies to the mobile stations 112 to 114. The mobile station 111 includes an antenna 405, an RF transceiver 410, a transmission processing circuit 415, a microphone 420, a reception processing circuit 425, and a speaker 430. The mobile station 111 includes a main processor 440, an input / output interface 445, a keypad 450, a display unit 455, a lagging feature (LF) button (not shown), and a memory 460. .

The RF transceiver 410 receives a signal transmitted from the base station 101 from the antenna 405. The RF transceiver 410 frequency converts the received RF signal into an intermediate band signal or a baseband signal. The midband signal or baseband signal is input to receive processing circuit 425 for filtering, decoding, and / or digital conversion processing. The receiving processing circuit 425 transmits the baseband signal from the process to the speaker 430 or the main processor 440 for further processing. As described above, the inputted to the speaker 430 may include voice data included in the processed baseband signal, and the inputted input to the main processor 440 may be related to the web search. If there is.

The transmit processing circuit 415 receives analog or digital voice data via the microphone 420, or other transmit baseband data from the main processor 440, such as web data, email, interactive video game data, or the like. Receive The transmit processing circuit 415 encodes, multiplexes and / or digitally converts the transmit baseband data to generate a baseband or midband signal. The RF transceiver 410 receives the baseband or midband transmission signal from the transmission processing circuit 415 and converts the frequency into an RF signal for transmission through the antenna 405.

According to an embodiment of the present disclosure, the main processor 440 may include a microprocessor or a microcontroller. The memory 460 connected to the main processor 440 may include random access memory (RAM) and / or read-only memory (ROM). The main processor 440 executes a basic operating system program 465 stored in the memory 460 to control the overall operation of the mobile station 111. In the control operation, the main processor 440 controls the forward channel signal reception and the reverse channel signal transmission through the RF transceiver 410, the reception processing circuit 425, and the transmission processing circuit 415. The main processor 440 may write or withdraw data to and from the memory 460 when necessary.

Memory 460 further includes a power level controller 470 and a probe message controller 475. Although shown separately, power level controller 470 and probe message controller 475 may be implemented in a single device.

The power level controller 470 adjusts the power level that the mobile station 111 uses for message transmission. For example, the power level controller 470 may determine the initial power level of the probe to send to the base station 101 according to the APM previously received at the base station 101. In addition, the power level controller 470 may determine the power increase based on the APM. Power level controller 470 increases the power level by the power increment when transmitting subsequent probes in the same connection sequence.

Probe message controller 475 provides power level indicator and service area indicator to base station 101. Probe message controller 475 when mobile station 111 executes a system attach procedure to connect to wireless network 100 for services such as call origination, call answering, registration, data burst request or response, order request or response, and the like. Generates a probe message comprising a probe number as a power level indicator and a connection sequence number as a service area indicator. In one embodiment, the probe message may have an ARQ message. In a particular embodiment, the ARQ message includes a 4-bit field for setting the probe number and a 4-bit field for setting the connection sequence number.

The mobile station 111 transmits the probe message to the base station 101 through an access probe. Mobile station 111 may send the probe message to base stations 102 and 103 or to one or more base stations.

If the mobile station 111 does not receive the accept response signal for the probe message within a predetermined time, the power level controller 470 increases the global level of the connected probe. The probe message controller 475 also generates an update probe message that includes the updated probe number and the connection sequence number. The mobile station 111 may transmit the update probe message to the base station 101.

The power level controller 470 may determine whether the power level has reached the maximum value according to the maximum number of transmission probes for a particular connection sequence. When the power level reaches a maximum, the mobile station 111 starts a new connection sequence. In one embodiment, the maximum probe number may be provided by the base station 101 through APM or other suitable communication method. In another embodiment, the maximum probe number may be preset.

To begin a new connection sequence, power level controller 470 reduces the power level to the initial power level and sends the corresponding probe message generated by probe message controller 475. The mobile station 111 continues to operate until it reaches the maximum access sequence number or receives an accept signal from the base station 101. Like the maximum probe number, the maximum access sequence number is provided by the base station 101 by APM or other suitable communication method. In another embodiment, the maximum access sequence number may be set in advance.

The main processor 440 is connected to the input / output interface 445. The input / output interface 445 allows the mobile station 111 to be connected with other devices such as notebook computers, portable computers, and the like. The input / output interface 445 provides a communication path between these devices and the main processor 440. The main processor 440 is connected to the keypad 450 and the display unit 455. The user of the mobile station 11 enters data into the mobile station 111 using the keypad 450. The display unit 455 may include a liquid crystal display panel (LCD) capable of displaying text and / or graphics from web sites. As another example, other types of display units may be used.

5 is a control flow diagram in determining a power level for communication with a wireless network in a mobile station in accordance with the present invention. For simplicity and clarity of explanation, in the following example, it is assumed that the base station 101 of the wireless network 100 provides a service to the mobile station 111. However, the following description applies equally to the remaining base stations and mobile stations in the wireless network 100.

In step 505, the mobile station 111 receives the APM from the base station 101 for the first time. The APM includes information that the mobile station 111 will use when attempting to access the base station 101 to request a service. For example, the APM may include, in the initial probe, the initial power level to be used by the mobile station 111 and the power increment to be applied to each subsequent probe transmitting in a particular connection sequence. The APM may also include a maximum probe number and / or a maximum access sequence number.

In step 510, the mobile station 111 determines to communicate with the base station 101 and prepares to send a probe to the base station 101 based on the APM. The probe message controller 475 of the mobile station 111 generates an initial probe message having a probe number and a connection sequence number in step 520. In one embodiment, the probe message includes an ARQ message. According to a specific embodiment, the ARQ message may include a 4-bit field for the probe number and a 4-bit field for the access sequence number. The mobile station 111 transmits the probe message to the base station 101 through the first probe in step 525.

If a response to the probe is not received from the base station 101 within a predetermined time in step 530, the power level controller 470 of the mobile station 111 determines whether the probe number is the maximum in step 535. The maximum probe number may be preset or determined by the base station 101 through the APM or through some other suitable method. In a particular embodiment, the maximum probe number may be set to 16.

If the maximum probe number has not yet been reached in step 535, in step 540, the power level controller 470 increases the power level for probe transmission according to the power increase provided by the base station 101 through the APM. Before generating another probe message with the updated probe number in step 520, the probe message controller 475 also increments the probe number in step 545.

If the maximum probe number is reached in step 535, the power level controller 470 determines whether the connection sequence number is the maximum in step 550. The maximum access sequence number may be preset or determined by the base station 101 through the APM or through some other suitable method. In a particular embodiment, the maximum access sequence number may be set to 16.

If the maximum access sequence number has not yet been reached in step 550, the probe message controller 475 increments the access sequence number in step 555 before starting another connection sequence in step 515. However, if the maximum access sequence number has been reached in step 550, the connection attempt of the mobile station 111 has failed and the procedure ends.

If a response to the probe is received from the base station 101 in step 530 within the predetermined time, the mobile station 111 starts communicating with the base station 101 at the same power level used in the successful probe transmission in step 560. In step 565, the mobile station 111 may receive the updated APM from the base station 101 according to the power level of the successfully transmitted probe. The procedure then ends. For example, the base station 101 may set the initial power level to be used by the mobile station 111 in the future probe to the detected power level to increase the probe success rate earlier in the access sequence. In addition, the base station 101 may adjust the maximum probe number and / or the maximum access sequence number. For example, the base station 101 can reduce the maximum probe number so that the final power level before the new connection sequence starts has the same value.

Meanwhile, in the detailed description of the present invention, specific embodiments have been described, but various modifications are possible without departing from the scope of the present invention. Therefore, the scope of the present invention should not be limited to the described embodiments, but should be determined not only by the scope of the following claims, but also by the equivalents of the claims.

As described above, by using the method according to the present invention, it is possible to reduce the procedure required for the connection attempt, and by efficiently managing the power of the transmitted and received messages, to determine the service defect in the wireless communication network and to solve the link imbalance There is an advantage that the communication is more smooth.

Claims (20)

A method of determining a power level for communication in a mobile station of a wireless network capable of communicating with a plurality of mobile stations located within an area of a wireless network, the method comprising: Generating a probe message for requesting a system connection to a base station, comprising a power level indicator indicating a predetermined transmit power level; Transmitting the probe message to a base station at the predetermined power level. 2. The method of claim 1, further comprising receiving a connection parameter message from the base station, the connection parameter message comprising an initial power level and a power level increment. The method of claim 2, wherein the power level indicator, And a probe number of the probe message, wherein the connection parameter message further includes a maximum probe number. The method of claim 1, Receiving a response to the probe message from the base station; And communicating with the base station at the predetermined power level. The method of claim 1, wherein the probe message, A method for determining power level for communication in a wireless network comprising an automatic retransmission request message. The method of claim 1, And transmitting the probe message to a plurality of base stations. The method of claim 1, And the power level indicator includes a probe number of the probe message. The method of claim 1, And the probe message further comprises a service area indicator. The method of claim 8, wherein the service area indicator, And a connection sequence number indicating a connection sequence associated with the probe message. A mobile station apparatus for determining a power level for communicating with a wireless network in the wireless network that can communicate with a plurality of mobile stations located within an area of a wireless network, A power level controller for adjusting the power level of messages transmitted from the mobile station; A probe message controller comprising a power level indicator indicating a predetermined transmit power level for transmitting a probe message, the probe message controller generating a probe message requesting a system connection of the mobile station to a base station; And a transmitter for transmitting said probe message to said base station at a predetermined power level. The method of claim 10, A receiver for receiving a connection parameter message from the base station, And the power level controller determines an initial power level of a probe message sent to the base station according to the connection parameter message. The method of claim 11, wherein the power level controller, And determine power increase in accordance with the connection parameter message. The method of claim 11, wherein the power level indicator, A probe number of the probe message, and the connection parameter message includes a maximum probe number. The method of claim 10, wherein the probe message, A mobile station device for communication in a wireless network, comprising: an automatic retransmission request message. The method of claim 10, wherein the power level indicator, Mobile station apparatus for communication in a wireless network, comprising a probe number of the probe message. The method of claim 10, wherein the probe message, And a service area indicator further comprising: a mobile station apparatus for communication in a wireless network. The method of claim 16, wherein the service area indicator, And a connection sequence number indicating a connection sequence associated with the probe message. A method of determining a power level for communication at a base station of a wireless network capable of communicating with a plurality of mobile stations located within an area of a wireless network, the method comprising: Receiving a probe message requesting a system connection, the probe including a power level indicator indicating a predetermined probe message transmission power level; Detecting the predetermined power level in accordance with the power level indicator. The method of claim 18, Generating a connection parameter message comprising an initial power level and a power level increment; Transmitting the connection parameter message to the mobile station. The method of claim 19, And determining the initial power level in accordance with the predetermined power level.

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